PL179334B1 - System for transmitting voice messages and method of making effective use of orthogonal modulation components - Google Patents

Abstract

A modulation scheme (600) useful in a voice paging system in which both of two orthogonal modulation components (500 and 510) are used to carry two halves of a single voice message destined for a receiver, or two separate voice messages for a receiver. The single voice message is transmitted in half the time.

Description

The invention relates to a method for transmitting voice messages.

More particularly, the invention relates to a method for transmitting voice messages in paging systems using orthogonal modulation components.

In an RF communications system that transmits voice messages to handhelds or other selective call receivers (e.g., paging receivers), single-sideband modulation techniques are used to efficiently utilize the frequency band. Only one of the top or bottom sidebands is used to transmit information to the receiver. Demodulating and reproducing a message that is transmitted entirely in the upper or lower sideband requires the receiver to sample both the phase I and quadrature Q components during transmission of the message on the channel. Both sidebands are recreated, but the message is contained in only one sideband. Information in the second sideband is discarded.

The fact that only one sideband actually carries the message means inefficient use of time, resulting in reduced traffic efficiency in the allocated radio frequency band. Moreover, this results in inefficient use of the receiver processing power and unnecessary consumption of the portable receiver battery.

The method for transmitting voice messages according to the invention is characterized in that when transmitting a message in the speech splitter, the message is split in time into first and second message parts, which are temporally adjacent parts of this message, then the first and second orthogonal components are orthogonally modulated in the orthogonal modulator. first and second orthogonally modulated components, respectively, are produced and transmitted through the antenna simultaneously to the receiver, where the received signal comprising the first and second orthogonally modulated components is orthogonally demodulated to obtain first and second message parts that are the temporarily contiguous parts of one message, the first and second message parts are then sequenced in time, combined in time and one message composed of the first and second message parts is generated.

Preferably, orthogonal modulation produces a phase component and a quadrature component, with the phase component modulating with a first message portion and the quadrature component modulating with a second message portion.

Preferably, orthogonal modulation produces an upper and a lower sideband with the upper sideband modulating with a first message portion and the lower sideband modulating with a second message portion.

Preferably, the first and second message parts comprise one voice message.

Preferably, the first and second message parts include one voice message, which is filtered with a bandpass filter and outside the normal audio bandwidth before splitting it in time into first and second message parts.

Preferably, prior to the orthogonal modulation, at least one message portion is temporarily inverted, the reversal in time being performed frame-by-frame based on the transmission protocol in a predetermined order.

Preferably, before orthogonal modulation, the first and second message parts are time compressed in a time compressor and the amplitude dynamics of the first and second message parts are reduced in the amplitude compander.

Preferably, the first and second orthogonally modulated components are transmitted simultaneously in a protocol containing address information corresponding to the address of the addressable receiver and including timing information to trigger the addressable receiver and enter an operating mode of simultaneously demodulating the first and second orthogonally modulated components at a specific point in time according to the timing information.

Preferably, upon receipt of the message, at least one of the message parts is time-backed before the timing of the first and second message parts.

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Preferably, the first and second message parts are digital signals which are then converted into analog signals.

The subject matter of the invention in the exemplary embodiments is reproduced in the drawing, in which Fig. 1 shows a radio communication system with selective calling in a block diagram; Fig. 2 illustrates the frequency band of the sub-channel; Fig. 3 is a transmitter of the communication system of Fig. 1, in a block diagram; Fig. 4 is the transmitter amplitude dynamics reducer module of Fig. 3, in a block diagram; Fig. 5 is an orthogonal modulator of the transmitter of Fig. 3 in a block diagram; Fig. 6 is another embodiment of an orthogonal transmitter modulator of Fig. 3, in a block diagram; Fig. 7 shows the pulse characteristic of the Hilbert filter of the orthogonal modulator of Figs. 5 and 6; Fig. 8 is a block diagram of the transmitter interpolator of Fig. 3; Fig. 9 is a pulse characteristic of the interpolator filter of Fig. 8; Fig. 10 is a block diagram of the use of a time-inverting module in the transmitter of Fig. 3; Fig. 11 shows a voice prompt; Fig. 12 is a digital representation of the voice message of Fig. 11; Figures 13 and 14 are digital representations of two halves of the voice message of Figure 11; Figs. 15-17 are examples of transmission protocol in timing diagrams, and Fig. 18 shows the selective call receiver of the communication system of Fig. 1 in a block diagram.

The radio communication system 100 shown in Fig. 1 includes message entry devices, i. E., Telephone 101, facsimile device 120, and message terminal 122, coupled to control the system 102 over the conventional PSTN public telephone network 108 and conventional telephone lines 110. System controller 102 oversees the operation of the plurality of radio frequency transmitters / receivers 103 over one or more telecommunications links 116, which may be twisted pair telephone lines, radio links, microwave links, or other high quality telecommunications links. System controller 102 encodes and decodes incoming and outgoing telephone addresses into computer-compatible switching messages on land lines. System controller 102 also encodes and orders outbound messages, including analog voice messages, digital numeric messages, and response orders, for transmission via RF transmitters / receivers 103 to multiple selective call receivers 106 (also called selective call radio receivers) to indicate that that they are able to send a message or confirm receipt back. System controller 102 further decodes incoming messages, including unforeseen messages and reply messages received by radio frequency transmitters / receivers 103 from the plurality of selective call receivers 106.

Examples of response messages are acknowledgments and designated response messages. The acknowledgment is a response to an outbound message initiated by the system controller 102. An example of an outbound numeric message intended for a selective call radio receiver 106 is a numeric paging message introduced by a telephone set 101. An example of an outgoing analog message intended for a selective call radio receiver 106 is a voice paging message. entered by a telephone 101. For these examples, an acknowledgment means successful receipt of an outgoing numeric or analog message.

The designated response message is a message sent from the selective call radio receiver 106 in response to a command contained in a message originating from the system controller 102. An example of a designated response message is a message initiated by the selective call radio receiver 106, but one that is only transmitted upon receipt from the controller 102. system 102 of the Designated Response Order. The designate reply command is in turn sent by the system controller 102 after transmitting from the selective call radio receiver 106 to the system controller 102 a message requesting the permission to transmit the designated response message. The reply message is transmitted at a time specified within the outgoing message or instruction. However, it may alternatively be transmitted using the protocol

179 334 non-scheduled, such as the known ALOHA protocol (Transmission Channel Access Algorithm) or the slotted ALOHA protocol.

An unforeseen message is an incoming message transmitted by the selective call radio receiver 106 without receiving an outbound message requiring a response. An example of an unforeseen message is a message arriving from selective call radio receiver 106 that alerts radio system 100 that selective call radio receiver 106 is within range of radio system 100. An unforeseen message may include a request to transmit a designated response and may include numerical data. Unforeseen messages are transmitted using the ALOHA protocol or the slotted ALOHA protocol.

The outgoing and incoming messages are included in the outgoing and incoming radio signals transmitted and received by a conventional antenna 104 coupled to the radio frequency transmitter / receiver 103.

Radio communication system 100 includes a plurality of fixed areas 115, each of which includes a system controller 102, an RF transmitter / receiver 103, a communications link 116 that interfaces the system controller 102 with the RF transmitter / receiver 103, and an antenna 104.

The system controller 102 can operate in a distributed broadcast control environment which allows mixing conventional cellular systems, satellite broadcast systems, or other coverage area systems associated with multiple radio frequency transmitters / receivers 103 and conventional antennas 104, providing certain radio signals over a geographic area as large as possible. like a world network.

Each of the selective call radio receivers 106 for use in radio system 100 is associated with at least one address that is a unique selective call address. This address allows the transmission of a message from the system controller 102 to only the addressed selective call radio receiver 106.

According to the invention, voice messages are sent on one of the plurality of sub-channels. Figure 2 shows the frequency band of one sub channel. In a preferred embodiment of the invention, the radio frequency channel comprises three sub-channels, the radio frequency channel having a width of e.g. 25 kHz. Alternatively, seven sub-channels can be used on a 50 kHz channel. It is obvious that other numbers of sub channels may be used depending on the bandwidth of the channel. The sub-channel spacing is 6250 Hz. Each subchannel has an upper sideband 500, a lower sideband 510, and a pilot carrier frequency 520. The upper sideband 500 and lower sideband 510 are used to carry segments of one message or two separate messages. The bandwidth allocated to the voice in one subchannel is 2500 Hz and covers an acoustic band from 300 to 2800 Hz.

The messaging process 600, especially the analog voice messages S (n), is performed by the radio frequency transmitter / receiver 103 or by the system controller 102. In either case, the information is transmitted according to one of the transmission protocols shown in Figs. 15-17.

Incoming voice message S (n) over the telephone line 110 is received by the system controller 102. If, for example, the telephone line is a T1 line, then the voice message S (n) is encoded using a pulse code modulation of 64 kbps and converted by the analog-to-digital converter 605 at 8 kHz sampling rate into a linear 16-bit digital form. Regardless of the link type, the voice message of the conventional analog telephone line is converted by the analog-to-digital converter 605 into a suitable digital form. Then, the digital form of the voice message is passed through a bandpass filter 610 in which frequencies outside the 300-2800 Hz acoustic band are filtered out. The filtered digital voice message is then passed through the module

179 334 of the automatic gain control ARW 620 to compensate for amplitude fluctuations of the incoming speech. Such fluctuations arise e.g. when the person speaks to the handset of telephone handset, cordless telephone, cellular telephone, etc. Automatic gain control module 620 improves intelligibility and further ensures that the power of the pilot carrier frequency that is added to the transmitted signal is always below a fraction of that signal strength. Automatic gain control 620, which has e.g. a rise time constant of about 2.5 ms and a fall time constant of 2 s, serves to maintain a constant speech power over a wide range of voice samples without disturbing the speech parameters. It does not mean that these parameters are limited.

The digital voice message is then time compressed in a compressor 630. Any number of compressors may be used. Thereafter, the digital voice message is fed to the compandor 640, where the signal dynamics is reduced to a ratio of about, e.g., 2: 1 dB, to prevent channel noise.

According to one embodiment of the invention, the first and second orthogonal modulation components are used to carry the segments Sa (n) and Sb (n) of one voice message. According to a second embodiment, these orthogonal modulation components are used to carry separate first S1 (n) and second S2 (n) voice messages. In both embodiments, the first and second components of the orthogonal modulation are either the upper sideband 500 and the lower sideband 510, respectively, or the phase (I) component and the quadrature component (Q) (also referred to as "channels"). Moreover, irrespective of the modulation scheme used, it is also possible to orthogonally modulate the first and second orthogonal components of the first message part Sa (n) and the second message part Sb (n), respectively, to form the orthogonally modulated first and second components.

Speech splitter 650 is used when one message is to be carried by both the first and second orthogonal modulation components. At the output of speech splitter 650, there are a first voice message portion Sa (n) and a second voice message portion Sb (n) temporarily composing the voice message S (n). However, if two separate voice messages S1 (n) and S2 (n) are to be modulated on the first and second orthogonal modulation components, then speech splitter 650 is not used, and each of the two voice messages S1 (n) and S2 (n) is processed in parallel by modules 605-640 and 605'-640 '(not shown), respectively, before proceeding to the next modules.

A single voice message S (n) is temporarily split into a first message portion S (n) and a second message portion Sb (n) by a speech splitter 650. In the case of digital information, the speech splitter 650 divides at some point a table of numbers representing the processed voice message S (n) into two tables, for example at the zero crossing or some other convenient time event, somewhere near the temporal center of the voice message S (n).

Then the voice message portions Sa (n) and Sb (n) (or the voice messages S1 (n) and S2 (n)) are fed to an orthogonal modulator 660 which modulates them on the first and second orthogonal modulation components.

Then, in an adder 705, a pilot carrier frequency that has an amplitude of approximately 0.15 of the maximum amplitude in speech information is added to the output of the orthogonal modulator 660.

Prior to this point in transmitter processing, the modules are operating, for example, at a sampling rate of 8 kHz. When this is finally converted to analog information, mirror signals occur at multiples of 8 kHz. In order to eliminate them, a filter suppressing mirror signals would be necessary. Consequently, to avoid this, the processed signal is interpolated in the interpolator 710 to a sampling rate of 16 kHz such that the mirror signals are spaced apart every 16 kHz. An analog filter is used to eliminate images in the processed analog information.

The output signals from interpolator 710 are then converted from digital to analog using a 16-bit D / A converter 720. Analo

The output signal from the DAC 720 is then fed to the appropriate analog playback (anti-mirror) filter 730 to remove all mirror signals leaving only the baseband signal of single-sideband transmission (SSB).

Quadrature amplitude modulation (QAM) 740 is coupled to the output of the reproduction filter 730 to modulate the SSB single bandwidth baseband signal to an appropriate sub channel where the signal is transmitted through antenna 750.

Figure 4 shows in detail the amplitude compandor 640 which reduces the dynamics of the signal amplitude. The reduction of the signal amplitude dynamics consists in increasing the components of the signal with a small amplitude and lowering the components of the signal with a large amplitude. Thanks to this, the components with small amplitude are protected against the influence of channel noise, which ensures better intelligibility of speech and its better quality.

Amplitude compandor 640 produces the drive voltage factor c2 (n) by calculating the absolute mean value of the signal averaged over the N samples. This is achieved by applying two moving average filters. The first moving average filter 641 computes the absolute average of the N input samples, and the second moving average filter 642 computes the average of the N samples of the absolute average values obtained from the output of the first moving average filter 641.

In delay 643, the input signal is delayed by N -1 samples, and the output signal after reducing the amplitude dynamics is calculated from the relationship:

[Delayed sample x Compressor gain factor] / [Control voltage c2 (n)] ^1/2

In the embodiment shown in Fig. 4, the number of samples N = 48 and the gain factor = 0.140625 x N. Preferably, although not shown in Fig. 4, the signal after dynamics reduction is again filtered by a bandpass filter 300. -2800 Hz to eliminate harmonics that could be introduced due to dynamic reduction. A filter similar to the bandpass filter 610 in Fig. 3 is used.

Figures 5 and 6 illustrate two embodiments of an orthogonal modulator 660. In Fig. 5, the voice message parts modulate the top and bottom sidebands while in Fig. 6, the voice message parts modulate the I and Q components.

The orthogonal modulator 660 shown in FIG. 5 includes a first Hilbert transform 670 and a second Hilbert transform 680. Each of these circuits includes a 33-tap Hilbert filter 672 and 682, a 16-sample delay circuit 674 and 684 and a multiplier 676 and 686. 33 - Hilbert catch filters 672 and 682 produce the Q components, and the 16 sample delay modules 674 and 684 produce the I components. Multipliers 676 and 686 cause the 90 ° phase shift necessary for the Q component. The upper sideband I + j * Q is produced by adder 685, and the lower sideband I - j * Q is produced by adder 695.

In the configuration shown in Fig. 6, the orthogonal modulator 660 'includes a delay circuit 700, similar to delay circuit 674, and a Hilbert filter 701, similar to filter 672. A voice message portion Sa (n) or a message S1 (n) is passed through the delay circuitry. 700, and a voice message portion Sb (n) or message S2 (n) is passed through a Hilbert filter 701. The output of this Hilbert filter 701 is coupled to a multiplier 702 to phase shift 90 °. At adder 703, the output of delay circuit 700 is added to the output of multiplier 702. The output of adder 703 thus includes a modulated I-component voice message portion Sa (n) and a Q-modulated voice message portion Sb (n), or, in the second example, In an embodiment of the invention, it comprises a voice message S1 (n) modulated by component I and a voice message S2 (n) modulated by component Q.

An exemplary pulse characteristic of the 3-tap Hilbert filters 672,682 and 701 is shown in Fig. 7.

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Figure 8 shows an example of a known multiphase interpolator 710 and Figure 9 shows the pulse characteristic of this interpolator 710. Every second sample is zero, which reduces the complexity of the computation. In addition, the frequency response of the filter has a passband of 0-3 kHz, and the filter attenuation at 5600 Hz is 60 dB. In Fig. 8 H ₀ (z ² ) = h0 + z ' ¹ h2 + z' ² h4 + ....; and H ^ z ² ) = z ' ¹ [h1 + z' ¹ h3 + z ' ² h5 + ...]. Considering the alternation of zeros in the pulse characteristic and the polyphase representation, the calculation is reduced to 6 multiplications per sample at a sampling rate of 16 kHz per channel (I or Q). This is a significant improvement over the 21 multiplications per sample at 16 kHz sampling rate in direct implementation.

Optionally, neither one nor both message parts are time-reversed prior to modulation in the orthogonal modulator 660 (or 660 '). Figure 10, however, illustrates a timer 800 that may be connected to the output of the speech splitter 650 - if one message is transmitted, or to the output of the amplitude compandor 640 - if two separate message parts are transmitted. The timer 800 reverses the message portion in time so that it is transmitted back in time. In the case of a digital implementation of the present invention, the timer 800 reads a string of last to first numbers from the output of the speech splitter 650 or amplitude compandor. For example, the timer 800 may be a programmable counter counting backwards from the highest value to the lowest value.

By reversing the message portion in time, the broadcast voice information is "encrypted" and has some degree of security or confidentiality. The time-reversed portion of the speech signal will not be "readable" or understandable to the receiver randomly monitoring the channel. Thus, only those receivers that know in advance that the transmitted voice information is time-reversed can demodulate and make the transmitted signal understandable. A decision as to whether or not to use time inversion may be made within the frame-by-frame transmission protocol, based on a predetermined sequence known to the transmitter and receiver. An example of a sequence known to both a transmitter and a receiver is the binary coded address of the selective call receiver. Moreover, in the case where the I and Q channels are modulated, the simultaneous overlapping in the channel band of two voice message parts, one or both time inverted, prevents speech intelligibility at the randomly monitoring receiver.

An example of a voice message broadcast according to the invention is shown in Figs. 11-14. The voice message V _M (FIG. 11) has a length T _M. On sampling and digitization at analog-to-digital converter 605, the voice message S (n) is defined as a sequence of numbers 1 to N that are digital representations of the samples (FIG. 12). The digital representation of the voice message _Vm is split into two parts in the separating speech 650. The preferred point of separation of the voice message _Vm is the zero point on the time axis T _s. The digit value of sample k is therefore the value of the voice message at time T _s . The first message portion Sa (n) contains the digital values for the samples 1 to k, and the second message portion Sb (n) contains the digital values for the samples k + 1 to N, as shown in Figures 13 and 14, respectively. these message parts or both may be reversed in time, and the order of the numerical values, in the case of time reversal of both message parts, are indicated in parentheses [] in Figures 13 and 14.

If upper sideband 500 and lower sideband 510 are used to carry message parts, the upper sideband 500 is formed, e.g., by a first message portion, using a Hilbert transform pattern 670. The upper sideband carrying the first message portion is represented. by the expression I _Sa + jQ _Sa. Likewise, the lower sideband carrying the second message part (time-inverted or not) is represented by the expression I _Sb - jQ _Sb , generated by the Hilbert transform 680. As shown in Fig. 2, the first message part Sa (n) and the second message part Sb (n) sąprzenoszone by the upper sideband 500 and lower sideband 510. consequently, a voice message V _M of duration T _M is transmitted in half the time because half of the message is fOR iN

179 334 is carried by the upper sideband 500 and the other half is carried by the lower sideband 510.

The receiver normally detects both sidebands, especially if it uses digital signal processing, but discards one of the sidebands. If the message is compressed during transmission, both sidebands may be used to transmit the message halfway through transmission. Moreover, the receiver receives the same message half the time, consuming less power, since the power-consuming decoding circuit is only turned on half the time.

Similarly, in the case where the upper sideband 500 and the lower sideband 510 carry two separate messages, the first message S1 (n) is represented by I _Sł ⁺ jQsb and the second message S2 (n) is represented by I _s2 - jQs2> respectively, on output of Hilbert transformation systems 670 and 680.

With paging systems, parts of the voice message are transmitted according to a certain protocol. One such protocol is illustrated in Figs. 15 to 17. Fig. 15 is a timing diagram illustrating an example of a transmit encoding format of an outbound transmission protocol used in the radio system 100 of Fig. 1, which includes control frame elements 330, according to a preferred embodiment. invention. Control frames 330 are also classified as digital frames.

The transmission protocol is divided into protocol chapters which are: 310 hours, cycles 320, control frames 330, voice frames 430, blocks 340, and words 350. At each hour 310, one transmits up to fifteen four-minute, uniquely identified cycles 320. Typically all these fifteen cycles 320 at each hour 310. In each cycle 320, up to one hundred twenty-eight unambiguously identified 1,875 second frames comprising control frames 330 and voice frames 430 (as shown in FIG. 16) are transmitted. Usually one hundred and twenty-eight of all these frames are sent. One hundred and fifteen milliseconds of timing and frame information 331 and eleven uniquely identified blocks 340 of one hundred and sixty milliseconds are transmitted in each control frame 330. In the control frame 330, a data rate of either 3200 bits per second or 6400 bits per second may be used. The baud rate during each control frame 330 is communicated to the selective call radio receivers 106 during the timing signal and frame information 331. When the baud rate is 3200 bps, each block 340 contains 16 uniquely identified words. bits 3 50 (as shown in Fig. 15). When the data rate is 6400 bits per second, then each block 340 contains 32 uniquely identified 32-bit words (not shown). In each 32-bit word 350, at least 11 bits are used for error detection and correction and 21 bits or less are used for information in a known manner. The bits and words 350 in each block 340 are transmitted interleaved using known methods to enhance the error correction capability of the protocol.

The information is contained in the information fields of each control frame 330.1 such: in block information field B1 332 there is frame structure information, in address field AF 333 one or more selective call addresses, and in vector field VF 334 one or more vectors. This vector field 334 begins at the boundary of vectors 335. Each vector in vector field 334 corresponds to one of the addresses in address field 333. The boundaries of individual information fields are limited by these fields and vary depending on factors such as the type of system information contained in timing and frame information field 331, the number of addresses contained in address field 333, and the number and type of vectors contained in vector field 334.

The timing diagram in FIG. 16 illustrates the transmit encoding format of the outbound protocol used in the radio system 100 of FIG. 1, showing voice frame elements 430 according to an embodiment of the invention. Voice frames 430 are also classified as analog frames. The duration of the individual protocol chapters, i.e .: 310 hours, 320 cycles, 330 control frames and 430 voice frames are

Identical to that described with regard to Fig. 15, 179 334 are identical to each voice frame 430 having a header portion435 and an analog portion440. The information in the header portion 435 - the frame timing and information signal 331 - is the same as the frame timing signal 331 in the control frame 330. The header portion 435 is frequency modulated and the analog portion 440 of the voice frame 430 is amplitude modulated. The analog portion 440 in one of the orthogonal modulation components carries parts of the voice message. Figure 16 shows that the radio system includes three subchannels 441,442 and 443 each having a pilot subcarrier similar to that shown in Figure 1 and in which parts of a voice message may be transmitted.

In accordance with a preferred embodiment of the invention, the transition portion 444 includes amplitude modulated pilot subcarriers for at least three subchannels 441, 442 and 443. Each subchannel 441,442 and 443 includes an upper sideband signal 500 and a lower sideband signal 510 as shown in Fig. 2. and further has an associated channel I and channel Q. In the example shown in FIG. 16, the upper sideband signal 500 includes one message portion 415 which is the first portion of the first voice message, and a second portion, e.g. of the same message, is located in the lower sideband 510. the first voice message.

Fig. 17 is a timing diagram illustrating a control frame 330 and two voice frames 430 of the outbound protocol used in the radio communication system of Fig. 1, according to a preferred embodiment of the invention. An example of a null frame is shown here, which is a control frame 330. In the null frame there are four addresses 501, 502, 503 and 504 and four vectors 518,521,522,523. Two addresses 501 and 502 contain one selective call radio receiver address 106, while the other two addresses 503 and 504 are for the second and third selective call radio receiver 106. Individual addresses 501, 502, 503 and 504 are uniquely assigned to individual vectors 518, 521 , 522 and 523 by inserting into each address a pointer that indicates the protocol position (i.e., where this vector begins and what is the length) of the associated vector. According to a preferred embodiment of the present invention, the vector position is given by identifying the number of words 350 after the vector boundary 335 at which the vector begins and the length of the vector in the words. Note that the relative positions of the addresses and vectors are independent of each other. The dependencies indicated by the indicators are illustrated by arrows.

In the example shown in Fig. 17, the control frame vectors 518, 521, and 523 are uniquely associated with the message portion on one of subchannels 441 or 442. Specifically, vector 518 indicates an upper sideband 500 of subchannel 441, and vector 521 indicates a lower sideband 510 of subchannel 441. Likewise, vector 523 indicates both sidebands of subchannel 442. In the case of subchannel 441, this example thus shows that two different message parts are conveyed through the top and bottom sidebands. In the case of sub-channel 442, the two halves of one message part are carried through the top and bottom sideband. The control frame vectors 518, 521 and 523 include information indicating which sub-channel (i.e. what radio frequency) of the receiver should search for the voice message of the frame and information indicating whether two separate messages are to be reconstructed from a sub-channel or whether the first and second halves of one message are to be reproduced.

Referring to the transmission protocol, a method of transmitting the messages of the first and second messages to an addressable receiver according to the invention comprises orthogonal modulating the first and second orthogonal components with the first and second messages, respectively, to generate the first and second orthogonally modulated components, and simultaneously transmitting the first and second components. an orthogonally modulated component in a protocol that includes address information corresponding to the address of an addressable receiver and timing information suitable to wake the addressable receiver to an operating mode suitable for simultaneously demodulating the first and second orthogonally modulated components at a specific point in time according to timing information.

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One possible solution for the case where two different messages are simultaneously transmitted in the upper and lower sidebands (or on channels I and Q) is that one message is a direct voice paging message and the other is a voicemail message to be sent. be stored in the paging receiver.

As shown in Figure 18, Selective Call receiver 106 includes at least an antenna 840, a QAM 850 quadrature amplitude demodulator, frequency demodulator 860, decoder / driver 870, audio amplifier 872, loudspeaker 874, alarm 876, display 878, and control elements 880. The QAM 850 demodulator performs quadrature-amplitude demodulation of the signal detected by antenna 840 to recover the voice messages. Frequency demodulator 860 performs frequency demodulation to recover data and other non-analog messages. The output of frequency demodulator 860 is a data (digital data) constrained signal that is provided to decoder / driver 870 and includes transmission protocol information that is decoded at decoder / driver 870 to respond to it displaying or storing messages. data, direct the sub-channel to demodulate voice messages, activate alarm 876, etc.

The voice messages are played back by a series of processing circuits that operate on the I and Q output of the QAM 850 demodulator. The processing circuits are shown as 900-960 and are, for example, implemented by firmware in a digital signal processor or by software stored in the decoder / driver 870. W in the latter case, the processing circuits will be implemented by the decoder / controller 870.

If the message parts were modulated on the I and Q components, then they will be reconstructed directly from the output of the QAM 850 demodulator. If one or both message parts were time-reversed on transmission, then the reconstructed message parts will be reversed in time by the time reversing units. 900 and 910 in the correct order. As a result, the message portion S1 (n) is obtained at the output of the invert at time 900 and the message portion S2 (n) is received at the output of the invert unit at time 910.

On the other hand, if the message parts were modulated on the upper and lower sidebands, then the stored is passed through delay 920 and the Q component is passed through the Hilbert transform 930. The adder 940 adds the outputs of delay 920 and Hilbert transform 930. and adder 950 subtracts the output of the Hilbert transform 930 from the output of delay circuit 920. The reconstructed message parts are passed through the inverters 900 and 910 if they were time inverted during transmission.

The message parts Sa (n) and Sb (n) are processed by a time ordering adder 960 that temporarily connects the message parts Sa (n) and Sb (n) together to reconstruct the original message S (n).

Additional time decompression and amplitude decompression functions are performed to cancel the effects of compressions performed with modulation. Although not clearly shown in Fig. 18, the time decompression and amplitude decompression circuits are coupled to e.g. the output of a time ordering adder 960. Other sub-modulation processing is possible to improve the quality of the reconstructed signal.

179 334

179 334

179 334

179 334

delay system = 16 samples

delay system = 16 samples

FIG.5

179 334 entry χ (η)

Hq (z2)

Ηι (ζ2)

the output y (n) FIG. 8

FIG. 9

179 334

FIG. 7

amplitude compandor

time splitter and invertor j __________I ----------------------------- FIG. 10

179 334 module

VM

Tm

Ts

FIG.ll

FIG.12

Sa (n)

FIG. 13

FIG.14

179 334

WD WD WD WD WD WD WD WD WD WD WD WD WD WD WD WD 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15

350 ³⁵⁰ 350- ^ 350 ^ 350 ^ ⁷ 350

FIG. 15

179 334

FIG. 16

179 334

179 334

Publishing Department of the Polish Patent Office. Circulation of 70 copies

Price PLN 4.00.

Claims (10)

Patent claims A method for transmitting voice messages, characterized in that when transmitting a message in a speech splitter, the message is split in time into first and second message parts which are temporarily adjacent to this message, then the first and second orthogonal first and second orthogonal components are orthogonally modulated in the orthogonal modulator and with the second message part, respectively, the first and second orthogonally modulated components are generated and transmitted through the antenna simultaneously to the receiver, where the received signal containing the first and second orthogonally modulated components is orthogonally demodulated and the first and second message parts are obtained, which are time contiguous parts of one message the first and second message parts are then sequenced in time, combined in time, and one message composed of the first and second message parts is generated. 2. The method according to p. The method of claim 1, wherein orthogonal modulation produces a phase component and a quadrature component, wherein the phase component is modulated with a first message portion and the quadrature component is modulated with a second message portion. 3. The method according to p. The method of claim 1, wherein the orthogonal modulation produces an upper and a lower sideband, the upper sideband modulating with a first message portion and the lower sideband modulating with a second message portion. 4. The method according to p. 3. The message as claimed in claim 1, 2 or 3, characterized in that the first and second message parts comprise one voice message. 5. The method according to p. The method of any of claims 1, 2 or 3, characterized in that the first and second message parts comprise one voice message, which before splitting it in time into first and second message parts, the bandpass filter is filtered by a filter and the frequencies outside the normal audio band are eliminated. 6. The method according to p. The method of any of claims 1, 2 or 3, characterized in that prior to the orthogonal modulation, at least one message portion is temporarily inverted, said reversing being performed frame-by-frame based on a transmission protocol according to a predetermined order. 7. The method according to p. The method of any of claims 1 or 2 or 3, characterized in that prior to orthogonal modulation the first and second message parts are compressed in time in a time compressor and the amplitude dynamics of the first and second message parts are reduced in the amplitude compander. 8. The method according to p. 3. The method of claim 1, 2, or 3, characterized in that the first and second orthogonally modulated components are simultaneously transmitted in the protocol containing address information corresponding to the address of the addressable receiver and containing the synchronization information enabling the triggering of the addressable receiver and entering the operating mode of simultaneous demodulation of the first and second orthogonally modulated component in a specific according to the timing information. 9. The method according to p. The method of claim 1, wherein at least one of the message parts is time-reversed before the first and second message parts are timed. 10. The method according to p. The method of claim 9, characterized in that the first and second message parts are digital signals which are then converted into analog signals. * * * 179 334